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Course, academic year 2024/2025
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Macroscopic Quantum Phenomena I - NFPL171
Title: Makroskopické kvantové jevy I
Guaranteed by: Department of Low Temperature Physics (32-KFNT)
Faculty: Faculty of Mathematics and Physics
Actual: from 2018
Semester: winter
E-Credits: 3
Hours per week, examination: winter s.:2/0, Ex [HT]
Capacity: unlimited
Min. number of students: unlimited
4EU+: no
Virtual mobility / capacity: no
State of the course: taught
Language: Czech
Teaching methods: full-time
Teaching methods: full-time
Guarantor: RNDr. Zdeněk Janů, CSc.
prof. RNDr. Ladislav Skrbek, DrSc.
Teacher(s): RNDr. Zdeněk Janů, CSc.
prof. RNDr. Ladislav Skrbek, DrSc.
Annotation -
General introduction to superconductivity and superfluidity, phenomenology of superconductivity, BSC theory of superconductivity, experimental proofs of validity of BCS theory, Ginzburg-Landau theory of superconductivity, type 1 and 2 superconductors, magnetic flux quantization and vortices, weak superconductivity - Josephson effect, applications of Josephson junctions, SQUID, high temperature superconductivity.
Last update: T_KFNT (06.05.2003)
Course completion requirements - Czech

Písemná a ústní zkouška

Last update: Janů Zdeněk, RNDr., CSc. (07.06.2019)
Literature -

M. Tinkham, Introduction to superconductivity, McGraw Hill, Inc.

Last update: Janů Zdeněk, RNDr., CSc. (06.05.2019)
Requirements to the exam -

Written and oral exam

Last update: Janů Zdeněk, RNDr., CSc. (07.06.2019)
Syllabus -

1. Introduction to superconductivity (electrical resistance, critical parameters, ideal conductivity and Meissner effect, London theory, thermodynamic properties, isotope effect, interaction with electromagnetic radiation)

2. Bardeen-Cooper-Schrieffer microscopic theory (origin of attractive interaction, variation method, ground state energy, coherence coefficients, calculation of the critical temperature and critical thermodynamic field, temperature dependence of the gap, density of states, gap-less superconductivity, electron tunneling, coherence effects)

3. Ginzburg-Landau (GL) phenomenological theory (order parameter, energy, coherence length, GL equations, flux penetration length and coherence length, limits of validity of GL theory, surface energy, type 1 and type 2 superconductors, magnetic flux quantization and quantum vortices)

4. Spontaneous breaking of gauge symmetry

5. Properties of type 2 superconductors (intermediate state, mixed state, interaction energy of vortices, interaction of vortices with surface, vortex pinning, critical state, resistive state, critical current, magnetization loop, imaging of vortices)

6. Applications of superconductivity

7. Weak superconductivity (Josephson junction (JJ), Josephson effect, calibration transformation, influence of a static magnetic field on JJ, electrodynamics of JJ, voltage-current characteristics of JJ, macroscopic quantum interference)

8. Applications of weak superconductivity (tunnel junctions, SQUIDs, analog and digital circuits)

9. High temperature superconductivity (history, structural and chemical properties of materials, magnetic and transport properties, theory)

Last update: Janů Zdeněk, RNDr., CSc. (06.05.2019)
 
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